EP4110624B1 - Notradaufsatz für ein fahrzeugrad - Google Patents

Notradaufsatz für ein fahrzeugrad Download PDF

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Publication number
EP4110624B1
EP4110624B1 EP21707983.9A EP21707983A EP4110624B1 EP 4110624 B1 EP4110624 B1 EP 4110624B1 EP 21707983 A EP21707983 A EP 21707983A EP 4110624 B1 EP4110624 B1 EP 4110624B1
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EP
European Patent Office
Prior art keywords
wheel attachment
emergency wheel
claw
retaining
radially
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
EP21707983.9A
Other languages
German (de)
English (en)
French (fr)
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EP4110624A1 (de
Inventor
Konstantinos Tsiberidis
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
GV Engineering GmbH
Original Assignee
GV Engineering GmbH
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Filing date
Publication date
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Publication of EP4110624A1 publication Critical patent/EP4110624A1/de
Application granted granted Critical
Publication of EP4110624B1 publication Critical patent/EP4110624B1/de
Active legal-status Critical Current
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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60BVEHICLE WHEELS; CASTORS; AXLES FOR WHEELS OR CASTORS; INCREASING WHEEL ADHESION
    • B60B11/00Units comprising multiple wheels arranged side by side; Wheels having more than one rim or capable of carrying more than one tyre
    • B60B11/10Emergency wheels
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60BVEHICLE WHEELS; CASTORS; AXLES FOR WHEELS OR CASTORS; INCREASING WHEEL ADHESION
    • B60B15/00Wheels or wheel attachments designed for increasing traction
    • B60B15/26Auxiliary wheels or rings with traction-increasing surface attachable to the main wheel body
    • B60B15/263Traction increasing surface being located axially beside tire
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60CVEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
    • B60C17/00Tyres characterised by means enabling restricted operation in damaged or deflated condition; Accessories therefor
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60CVEHICLE TYRES; TYRE INFLATION; TYRE CHANGING; CONNECTING VALVES TO INFLATABLE ELASTIC BODIES IN GENERAL; DEVICES OR ARRANGEMENTS RELATED TO TYRES
    • B60C7/00Non-inflatable or solid tyres
    • B60C7/24Non-inflatable or solid tyres characterised by means for securing tyres on rim or wheel body
    • B60C7/28Non-inflatable or solid tyres characterised by means for securing tyres on rim or wheel body using straps or the like, e.g. vulcanised into the tyre
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60BVEHICLE WHEELS; CASTORS; AXLES FOR WHEELS OR CASTORS; INCREASING WHEEL ADHESION
    • B60B2310/00Manufacturing methods
    • B60B2310/30Manufacturing methods joining
    • B60B2310/307Manufacturing methods joining by removably mountable securing elements, e.g. circlips
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60BVEHICLE WHEELS; CASTORS; AXLES FOR WHEELS OR CASTORS; INCREASING WHEEL ADHESION
    • B60B2900/00Purpose of invention
    • B60B2900/70Adaptation for
    • B60B2900/731Use in cases of damage, failure or emergency

Definitions

  • the invention relates to an emergency wheel attachment for a vehicle wheel, which comprises a rim and a tire arranged on the rim, the emergency wheel attachment being intended to be placed on the outside of the vehicle wheel.
  • a generic emergency wheel attachment is from the document WO 2019/141817 A1 known.
  • Such an emergency wheel attachment is intended to enable a vehicle to continue driving if a tire is damaged and can therefore no longer hold air.
  • the defective vehicle wheel usually has to be removed from the vehicle and replaced with a spare wheel.
  • the emergency wheel attachment according to the invention is intended to be placed on the outside of the defective vehicle wheel and thus avoids the need to change the defective vehicle wheel.
  • an emergency wheel attachment In connection with such an emergency wheel attachment, it is particularly important that the emergency wheel attachment can be easily and yet extremely securely mounted on a vehicle wheel, because in a subsequent operating state of a vehicle wheel provided with the emergency wheel attachment, considerable forces act on the emergency wheel attachment and the latter must under no circumstances come off the vehicle wheel unintentionally solve.
  • Such an emergency wheel attachment should also be designed to be as space-saving and lightweight as possible in order not to unduly increase the energy consumption of a vehicle in which such an emergency wheel attachment is carried.
  • the invention therefore aims to provide an emergency wheel attachment for a vehicle wheel that can be easily and yet safely mounted on the vehicle wheel and that can be designed to be space-saving and lightweight at the same time.
  • an emergency wheel attachment for a vehicle wheel, which has the features specified in claim 1.
  • Such an emergency wheel attachment comprises a substantially annular mounting unit, which is used to mount the emergency wheel attachment on the vehicle wheel, and a substantially annular tread unit, which, in the operating state of the emergency wheel attachment, contacts a road on which the vehicle wheel provided with the emergency wheel attachment is intended to roll.
  • essentially annular assembly unit and tread unit is that the basic shape of the assembly unit and the tread unit is circular ring-shaped, but this does not exclude parts extending from the assembly unit and the tread unit that are not Circular ring shape is associated.
  • the assembly unit is provided with at least two retaining claws, which are designed to attach the assembly unit to the rim of the vehicle wheel by gripping behind the rim flange of the rim.
  • Embodiments of the emergency wheel attachment according to the invention usually have more than just two retaining claws, for example three, four, five or even six retaining claws.
  • At least one of the existing retaining claws is designed to be radially movable so that its distance from a center point of the assembly unit can be changed.
  • several or even all retaining claws can be designed to be radially movable.
  • the radial mobility of the at least one retaining claw makes it possible to initially arrange this retaining claw or all radially movable retaining claws in a radially further outward position in order to be able to place the assembly unit on the rim of the vehicle wheel in this state.
  • the retaining claws then grip behind the rim flange of the rim and the assembly unit is clamped on the rim.
  • the assembly unit has an annular actuating element which is rotatable about an axis which coincides with the vehicle wheel axle in the operating state of the emergency wheel attachment (i.e. when the emergency wheel attachment is attached to the vehicle wheel).
  • the annular actuating element forms part of a gear, which converts a rotation of the actuating element into a translational radial movement of the or all radially movable retaining claws.
  • the assembly unit is further provided with a drive device which is coupled or can be coupled to the actuating element and whose actuation leads to the rotation of the actuating element.
  • the annular actuating element is a chain and the drive device is a rotatable drive sprocket which is or can be brought into engagement with the chain.
  • each radially movable holding claw is provided with a holding arm which extends radially inwards from the holding claw and which has rack-like teeth on one side, which engages with a rotatable transmission pinion assigned to the holding claw, which in turn engages with the chain.
  • rotation of the drive sprocket is transmitted to the chain, which thereby moves in the circumferential direction and this movement is transferred to the transmission pinion or pinions, the rotation of which is converted into a radial movement of each movable retaining claw by means of the rack-like toothing present on each movable retaining claw, which runs either radially inwards or radially outwards depending on the direction of rotation of the drive pinion.
  • the assembly unit can have a correspondingly shaped housing.
  • the actuating element is an at least substantially annular actuating disk.
  • This actuating disk can have internal teeth or external teeth and the drive device can, as previously explained in connection with the chain, be a rotatable drive pinion, which is in engagement with the internal toothing or the external toothing or can be brought into engagement in order to be able to set the actuating disk in rotation .
  • the actuating disk can be provided with an annular series of recesses or openings and each movable holding claw can be assigned a pinion which engages with the recesses or openings in the actuating disk and is connected to a threaded spindle, which in turn is connected to an associated holding claw and which converts a rotational movement of the pinion into an at least substantially radially directed translational movement of the holding claw.
  • the recesses or openings are preferably slot-shaped and extend mainly in the radial direction.
  • Such an actuating disk is similar in appearance to a so-called resolver wheel, as used in connection with speed sensors, but has a completely different function.
  • the actuating disk has an internal toothing and an external toothing
  • the rotatable drive pinion is or can be brought into engagement with the external toothing and each radially movable retaining claw is assigned a gear, in particular designed as a bevel gear, which engages with the internal toothing of the actuating disk stands and is connected to a threaded spindle, which in turn is connected to an associated retaining claw and a rotational movement of the (bevel) gear in at least one Substantially radially directed translational movement of the holding claw is implemented.
  • the rotatable drive pinion of the assembly unit is located at a location slightly radially outside the actuating disk, thereby allowing a central free space in the center of the assembly unit to be maximized.
  • This can be advantageous in connection with vehicle wheel rims that have a so-called overlap, ie for rims whose middle region protrudes axially further than radially outer regions of the rim. If the mounting unit has as large a central free area as possible, then the mounting unit can be mounted close to the vehicle wheel, even with rims that have an overlap, without colliding with the rim.
  • the rotatable drive pinion of the assembly unit can engage with the internal toothing.
  • the external teeth of the actuating disk can then be omitted.
  • the actuating disk has an internal toothing or an external toothing and the drive device is in turn a rotatable drive pinion, which is in engagement or can be brought into engagement with the internal toothing or the external toothing in a similar manner to the previously explained modification.
  • each movable holding claw is provided with a holding arm which extends radially inwards from the holding claw and which has rack-like teeth on one side, which is in engagement with a rotatable transmission pinion assigned to the holding claw, which in turn is engaged with the internal teeth or the external teeth of the actuating disk.
  • This embodiment is similar to an embodiment described above, in which the actuating element is designed as a chain.
  • the transmission pinion or one of the transmission pinions can also function as a drive pinion.
  • the or one of the transmission pinions can also be the drive pinion. In this way, a housing of the assembly unit can be made simpler, since there is no need for separate storage of the drive pinion, and components can be saved.
  • the actuating disk has at least one spiral segment-shaped link which interacts with a sliding block which is arranged on a holding arm connected to a radially movable holding claw. If the actuating disk, which has at least one spiral segment-shaped link, is rotated, its movement is transferred to the associated retaining claw via the sliding block running in or on the link and ensures that the retaining claw changes its distance from the center of the assembly unit.
  • Each radially movable retaining claw is guided in such a way that it can only move in the radial direction, but not in the circumferential direction.
  • each retaining claw must be designed specifically for the associated circumferential position, so that all radially movable retaining claws in a starting position of the actuating disk have the same radial distance from the center of the assembly unit.
  • each radially movable holder claw must therefore be mounted at a very specific location associated with it when assembling the assembly unit.
  • the actuating disk can also have several spiral segment-shaped links arranged next to one another in the circumferential direction.
  • the radially movable retaining claws can all be designed in the same way and when assembling the assembly unit it is no longer necessary to ensure that each retaining claw is mounted in a location that is only suitable for it.
  • the several spiral segment-shaped links can also overlap in the circumferential direction, so that on each section of the actuating disk associated with a radially movable retaining claw, as seen in the radial direction, several spiral segment-shaped links are arranged next to one another.
  • the holding arm of one or each radially movable holding claw can then be provided with a plurality of sliding blocks arranged radially next to one another for engaging in the plurality of slots.
  • the or each sliding block can have the shape of a pin or bolt.
  • the or each sliding block can have the shape of a short spiral segment-shaped rib, the dimensioning and shape of the spiral segment-shaped rib being selected such that it can interact with an associated spiral segment-shaped link. Sliding blocks with other shapes are also conceivable, the only important thing is that the rotational movement of the actuating disk is transmitted from the link to the sliding block with as little loss as possible.
  • the or each link can be a spiral segment-shaped, slot-like opening in the actuating disk.
  • the or each link can be formed by a spiral segment-shaped link rib, which is or are formed on the actuating disk.
  • each retaining claw of the mounting unit serves to mount and securely fasten the mounting unit to the rim of the vehicle wheel.
  • each retaining claw has a contact section for contacting the rim flange and is further provided with at least one safety section arranged in the circumferential direction next to the contact section, which is in the operating state of the emergency wheel attachment, ie when the emergency wheel attachment is correctly mounted on a rim of a vehicle wheel. has a small radial distance from the rim flange. This distance should be in the range of 0.2 to 0.5 mm and is preferably about 0.3 mm.
  • the or each safety section of the retaining claw is arranged in the circumferential direction of the assembly unit next to the contact section and spaced from it by a slot. If the contact section is a middle contact section, then a safety section is preferably arranged on both sides of the middle contact section of the retaining claw. If, during operation of the emergency wheel attachment, the contact section of a retaining claw is overloaded and, as a result, the contact section fails, for example due to the contact section breaking off from the retaining claw, then the safety section or safety sections of the retaining claw in question ensure that this retaining claw does not move detached from the rim.
  • each safety section and the rim flange ensures, on the one hand, that if the contact section is overloaded, the safety section or the safety sections of the relevant retaining claw are not also overloaded, and, on the other hand, ensures that after a failure of the contact section, which originally rests on the rim flange without any play Contact section due to the play between the rim flange and the safety section a conditional rattling occurs, which indicates to a driver that something is wrong with the emergency wheel attachment.
  • a double claw has two retaining claw elements which are spaced apart from one another in the circumferential direction, with both retaining claw elements being attached to a common retaining arm.
  • Each retaining claw element of a double claw can, as described above, have a contact section and at least one safety section arranged next to it in the circumferential direction.
  • each retaining claw element comes into correct contact with the rim flange of a vehicle wheel
  • at least one of the retaining claw elements can be set up to be able to rotate to a small extent relative to the common retaining arm about an axis that is perpendicular to a plane spanned by the common holding arm. In this way, existing angular errors can be compensated for and tilting of a retaining claw element is prevented.
  • each retaining claw is provided with one or more recesses which are located on the side facing the tire and are arranged in the area of an end section of the holding claw, which is adjacent to the free end of the holding claw or encompasses the free end.
  • these recesses enable the rubber material of the tire to press into the recesses and thereby reduce the force that is exerted by the tire on the retaining claw when the retaining claw is inserted into the area mentioned.
  • each retaining claw is preferably equipped with a radially extending stop surface with which it rests on an outside of the rim, for example on the rim flange, in the operating state of the emergency wheel attachment. Furthermore, at least one and preferably each retaining claw is provided with an indicator element which is resiliently biased towards the rim Retaining claw penetrates in the area of the radially extending stop surface, one end of the indicator element facing the rim being intended for contacting the rim and an opposite, other end of the indicator element in the operating state of the emergency wheel attachment indicating correct assembly of the assembly unit.
  • a color-coded end of the indicator element protrudes from the side of the emergency wheel attachment facing away from the vehicle wheel, thereby indicating that the assembly unit has been correctly assembled.
  • this end of the indicator element can also be flush with a surrounding surface of the emergency wheel attachment if the assembly unit has been correctly assembled.
  • the or each indicator element can also be designed differently, provided that it is able to indicate that the radial stop surface is in correct contact with the outside of the rim.
  • the tread unit is a unit that is separate from the assembly unit and preferably consists of several circular ring segments, which is designed to be connected to the assembly unit and is connected to the assembly unit in the operating state of the emergency wheel attachment.
  • the tread unit is a unit consisting of two semicircular ring segments.
  • the tread unit consists of two circular ring segments, one of which occupies approximately two thirds of the circumference and the other circular ring segment occupies one third of the circumference. Still other configurations are conceivable, for example dividing the tread unit into three or more circular ring segments.
  • locating bolts are used to connect the tread unit to the assembly unit, which are arranged protruding on the side of the assembly unit facing away from the vehicle wheel. After the assembly unit has been attached to the vehicle wheel, the tread unit can be pushed onto the mounting bolts protruding from the assembly unit and attached to them.
  • the locating bolts can be attached to a housing of the assembly unit. Alternatively or additionally, the locating bolts can be attached to the retaining claws, in particular to the radially inwardly extending retaining arm of each retaining claw.
  • the locating pin also serves as a sliding block, for example by protruding through a link in the actuating disk which is designed as a spiral segment-shaped, slot-like opening.
  • the locating bolts Threaded bolts which enable the tread unit to be attached to the assembly unit by nuts with which the tread unit is screwed to the assembly unit.
  • the aforementioned nuts can be cap nuts and each cap nut can contain an optical and/or acoustic display device which signals a correct assembly status.
  • a cracking noise generated by a bistable sheet metal can signal that a torque necessary for correctly attaching the tread unit to the assembly unit has been achieved.
  • a pin protruding outwards from the cap nut or a pin flush with the outer surface of the cap nut can signal that the cap nut has been tightened correctly.
  • each locking device can comprise a radially movable slide arranged on the mounting unit, which is resiliently biased radially outwards, the slide having a ramp which comes into contact with an associated surface of the tread unit when the tread unit is mounted, so that the slide when Assembly process is shifted radially inwards and after the tread unit has been assembled, due to its resilient preload, it pushes itself radially outwards and over the surface of the tread unit and the tread unit is thereby locked in the correctly assembled position.
  • Modified versions of the locking device are also conceivable.
  • the design of the mounting unit does not necessarily have to be essentially annular, but differently designed mounting units can also be used, for example those in which several fastening arms extend radially outwards from a center of the mounting unit There is at least one retaining claw at each free end.
  • At least one self-bracing safety claw can be provided for gripping behind the rim flange of the rim in order to increase the fastening security.
  • the or each self-bracing safety claw is arranged on the side of the tread unit facing the vehicle wheel, with each safety claw preferably being arranged between two retaining claws when viewed in the circumferential direction of the emergency wheel attachment.
  • An exemplary embodiment may have three retaining claws and three self-tightening safety claws.
  • such self-bracing safety claws can also be provided on embodiments of the emergency wheel attachment that have more than just a relatively few retaining claws.
  • Each safety claw preferably has an actuating slide, one end of which passes through a running surface of the running surface unit and protrudes radially from the running surface.
  • the end of the actuating slide protruding radially from the tread is pressed radially inwards by contact with the road surface, as a result of which the other, radially inner end of the actuating slide is displaced radially inwards and comes into contact with the Safety claw presses the safety claw onto or behind the rim flange of the rim.
  • the or each actuating slide is resiliently biased radially outwards and has a locking device which, following a radially inward displacement of the actuating slide, prevents the actuating slide from moving radially outwards.
  • the locking device therefore ensures that the safety claw pressed onto or behind the rim flange of the rim by means of the actuating slide maintains this position.
  • plates made of spring steel can be used as a locking device, the free end of which interacts with a locking toothing on the actuating slide.
  • Other locking devices to prevent a radially outward movement of the actuating slide after actuation are conceivable.
  • the actuating slide which is resiliently biased radially outwards and protrudes radially from the running surface of the emergency wheel attachment, is used to move an associated safety claw radially inwards and is therefore referred to as an actuating slide.
  • a slide constructed and arranged in this way can also be used to secure a radially movable retaining claw, which has been brought into engagement with the rim flange by means of the described assembly unit of the emergency wheel attachment according to the invention, against unintentional loosening or loosening.
  • such a radially outwardly spring-loaded slide which passes through the running surface of the emergency wheel attachment, is arranged in an area of the emergency wheel attachment which is located radially outside of a radially movable retaining claw.
  • this slider which initially protrudes radially from the running surface, is then pressed radially inwards by contact with the road surface and the radially inner end of the slider is designed in such a way that it comes from radially outside onto the retaining claw, more precisely onto a retaining claw head Holding claw, presses.
  • the emergency wheel attachment by appropriately rotating the drive device, the or each movable retaining claw is moved radially inwards and the assembly unit is thereby clamped on the rim of the vehicle wheel.
  • preferred embodiments of the emergency wheel attachment are equipped with a torque limiting device for the drive device. If the drive device is a drive pinion that is coupled or can be coupled to the actuating element, then this drive pinion can be equipped with a Cap nut be connected, in which such a torque limiting device is located.
  • the torque limiting device can, for example, be a slip clutch consisting of several spring washers arranged one above the other.
  • the spring washers can have elevations and depressions that are designed to correspond to one another, so that after a predetermined torque is exceeded, the torque limiting device continues to rotate in sections, without, however, increasing the torque applied to the actuating element.
  • the assembly unit preferably has an at least substantially annular housing in which the actuating element is arranged.
  • a handle spanning the free center of the housing of the mounting unit is attached to the housing, the handle preferably being arched outwards in order to be easier to grip.
  • an emergency wheel attachment 10 for a vehicle wheel 12 which has a rim 14 and a tire 16 arranged on the rim (only in the Figures 21 and 22 shown).
  • the emergency wheel attachment 10 In its operating state (see Figure 2 ), the emergency wheel attachment 10 is placed on the outside of the vehicle wheel 12 and attached to the rim 14 of the vehicle wheel 12 in order to enable continued travel in the event of a tire damage.
  • the damaged tire 16 is usually still on the rim 14, unless the tire 16 has already been completely detached from the rim 14.
  • the functionality of the emergency wheel attachment 10 on the vehicle wheel 12 is given with or without tires 16.
  • the emergency wheel attachment 10 comprises a substantially annular mounting unit 18, which is used to mount the emergency wheel attachment 10 on the vehicle wheel 12, more precisely on its rim 14, and further comprises a substantially also annular tread unit 20, which in the operating state of the emergency wheel attachment 10 has a tread 21 contacts a road on which the vehicle wheel 12 with the emergency wheel attachment 10 mounted on it is supposed to roll.
  • the assembly unit 18 and the tread unit 20 form two separate assemblies that are mounted one after the other on the vehicle wheel 12.
  • the mounting unit 18 and the tread unit 20 may form a single interconnected unit that is mounted as such on a vehicle wheel 12.
  • the mounting unit 18 in the exemplary embodiment according to Figure 1 six retaining claws 22, the structure of which is shown in more detail Figures 23 to 31 emerges and which are in any case designed to grip behind a rim flange 26 of the rim 14 with a hook-like holding claw head 24 and to rest firmly on the rim flange 26 in the assembled state.
  • Figure 4 can be seen showing section IV-IV Figure 2 shows.
  • the six retaining claws 22 are arranged distributed over the circumference of the assembly unit 18 and each extend radially outwards.
  • the holding claws 22 can be arranged evenly spaced apart from one another in the circumferential direction in the exemplary embodiment according to Figure 1 However, arranged in two groups of three, of which one group of three retaining claws 22 is on the left side with respect to the section line IV-IV and the other group of three is on the right side of the assembly unit 18.
  • each retaining claw 22 is mounted in a radially guided manner in a substantially annular base body 28 of the assembly unit 18.
  • a radially extending groove 34 in the base body 28 is used for guidance is.
  • the retaining arm 36 is provided with a threaded bore 38 for receiving a threaded spindle 40, one end section of which is screwed into the threaded bore 38.
  • a pinion 44 designed here as a bevel (gear) wheel 42, is arranged on the threaded spindle 40.
  • An annular actuating element is used to couple the radially directed inward or outward movement of all radially movable holding claws 22, which according to the in Figures 1 to 4 illustrated, first embodiment is an annular actuating disk 46 with an internal toothing 48 formed on its inner circumference.
  • the actuating disk 46 is rotatably mounted on the base body 28 of the assembly unit 18 so that its internal teeth 48 are in engagement with each bevel gear 42.
  • a drive pinion 52 here also designed as a bevel gear, is rotatably mounted on an axial bearing pin 50 of the base body 28 and is in engagement with the internal teeth 48 of the actuating disk 46.
  • the drive pinion 52 is provided with a nut, designed here as a cap nut 54, which extends axially beyond the actuating disk 46.
  • a substantially annular cover 56 is fastened to the base body 28 with screws 58 and, together with the base body 28, forms a housing 60 of the assembly unit 18, in which the retaining claws 22 (partially), the bevel gears 42, the actuating disk 46 and the drive pinion 52 are located condition.
  • the cap nut 54 of the drive pinion 52 protrudes axially from the housing 60 through an opening 62 in the cover 56, so that the drive pinion 52 can be rotated using a wrench or other suitable tool.
  • Such a rotation of the drive pinion 52 leads to a rotation of the actuating disk 46 about an axis of rotation A, which coincides with the axis of rotation of the vehicle wheel 12 in the operating state of the emergency wheel attachment 10 (see Figure 4 ).
  • the rotation of the actuating disk 46 is transmitted to the bevel gears 42 of the holding claws 22, whereby all radially movable holding claws 22 are synchronously moved radially outwards or radially inwards, depending on the direction of rotation of the drive pinion 52.
  • the spindle nut arrangement formed by a bevel gear 42 and a threaded spindle 40 can either have a non-rotatable threaded spindle 40 and a bevel gear 42 rotatably arranged on the latter, or alternatively a bevel gear 42 arranged non-rotatably on the threaded spindle 40, in which case the threaded spindle 40 is free must be rotatably arranged in the threaded hole 38 of the holding arm 36.
  • all radially movable retaining claws 22 are positioned so that the assembly unit 18 can be placed on the vehicle wheel 12 from the outside in such a way that each retaining claw head 24 is located in the area of the rim flange 26, but radially slightly outside of it.
  • the assembly unit 18 is then pressed axially against the vehicle wheel 12 and at the same time the drive pinion 52 is rotated so that the holding claws 22 move radially inwards so that the holding claw heads 24 can grip behind the rim flange 26.
  • the rotation of the drive pinion 52 continues until the retaining claw heads 24 come into firm contact with the rim flange 26.
  • the drive pinion is 52 rotated until a predetermined torque, for example 60 Nm, is reached, which ensures that each retaining claw head 24 rests firmly on the rim flange 26 and thus the entire assembly unit 18 is reliably connected to the vehicle wheel 12.
  • locating bolts 64 designed here as threaded bolts, which protrude axially or at least substantially axially from the housing 60 of the assembly unit 18 on the side facing away from the vehicle wheel 12.
  • one such locating bolt 64 is fastened or formed on the holding arm 36 of each holding claw 22 and is therefore not strictly axially directed, but rather inclined at the angle ⁇ to the plane E.
  • the locating bolts 64 can protrude axially from the base body 28.
  • a series of positioning pins 66 are used to position the tread unit 20 on the assembly unit 18, which are fastened or formed here on the base body 28 and protrude axially outwards.
  • the tread unit 20 consists of two essentially semicircular segments 68 and 70, which are attached one after the other to the mounting unit 18 attached to the vehicle wheel 12.
  • Upper segment 68 is pushed onto the corresponding locating bolts 64 and positioning pins 66 (each segment 68 and 70 is provided with corresponding openings 72 and positioning recesses 74 for this purpose).
  • a cap nut 76 is then screwed onto the two upper locating bolts 64 extending through the segment 68 in order to press the segment 68 against the assembly unit 18 and fasten it to it.
  • the vehicle wheel 12 By moving a vehicle (not shown) equipped with the vehicle wheel 12 forwards or backwards, the vehicle wheel 12 is then rotated to such an extent that the segment 68, which is initially located at the top, reaches a lower position.
  • the tread 21 of the segment 68 comes into contact with the road surface on which the vehicle wheel 12 is located.
  • the second segment 70 of the tread unit 20 can be mounted in the same way as the segment 68.
  • the procedure is reversed, i.e. the cap nuts 76 are first loosened and the two segments 68, 70 of the tread unit 20 are removed one after the other from the assembly unit 18.
  • the drive pinion 52 of the mounting unit 18 is then rotated in a direction that causes the retaining claws 22 to move radially outward. After the retaining claw heads 24 have been released from the rear grip with the rim flange 26, the assembly unit 18 can be removed from the vehicle wheel 12.
  • the actuating disk 46 can have, in addition to the internal toothing 48, an external toothing which is intended to engage with the drive pinion 52.
  • the drive pinion 52 is in contrast to the one in Figure 1 Arrangement shown arranged radially outside the actuating disk 46.
  • the internal toothing 48 only serves to transmit the rotational movement of the actuating disk 46 to the bevel gears 42.
  • FIGS. 5 and 6 show a second embodiment of an emergency wheel attachment 10a that is slightly modified compared to the first embodiment.
  • the main difference is in the design of the actuating disk and the pinions assigned to the holding claws 22.
  • the annular actuating disk 46a of the second embodiment also has internal teeth 48, this only serves to come into engagement with the drive pinion 52, which in the second embodiment is designed as a normal spur gear.
  • the transmission of a rotary movement of the actuating disk 46a to the radially movable holding claws 22 takes place by means of a series of slot-shaped openings 80 in the actuating disk 46a, which engage with pinions 44a, which are each connected to the threaded spindle 40 of the associated holding claw 22.
  • the pinions 44a are normal spur gears.
  • the function of this second embodiment corresponds to that of the first embodiment and is good Figure 6 can be seen, which only represents the interaction between the drive pinion 52, the actuating disk 46a and the pinions 44a of the holding claws 22.
  • the second embodiment can be modified such that the drive pinion 52 is not arranged radially inside the actuating disk 46a, but rather radially outside the same.
  • the internal toothing 48 can then be omitted, but external toothing must be provided on the actuating disk 46a so that a rotational movement of the drive pinion 52 can be transmitted to the actuating disk 46a.
  • FIGS 7 and 8 show a third embodiment of an emergency wheel attachment 10b, which differs from the two previously described embodiments in that a chain 82 is used as an annular actuating element instead of an annular actuating disk.
  • a chain 82 is used as an annular actuating element instead of an annular actuating disk.
  • the assembly unit 18 (and this only partially) is shown.
  • the chain 82 is arranged and guided in a circular ring shape in the housing of the assembly unit 18.
  • a rotational movement of the drive pinion 52 rotates the chain 82 about the axis of rotation A and the chain 82 transmits this movement to transmission pinions 44b, which are rotatably mounted on the base body 28 and whose axis of rotation runs parallel to the axis of rotation A (in contrast to this, the axis of rotation is the pinion 44 and 44a of the first and second embodiments each show the essentially radial central longitudinal axis of the associated threaded spindle 40).
  • the radially extending holding arm 36b is provided on one side with a rack-like toothing 84, which engages with the associated transmission pinion 44b, which in turn engages with the chain 82.
  • Each rotational movement of the transmission pinion 44b is thus converted into a radial translational movement of the associated holding claw 22, which, depending on the direction of rotation of the drive pinion 52, is directed either radially outwards or radially inwards.
  • Figure 8 shows a modified embodiment of the third embodiment, in which the chain 82 does not run in a circular ring shape, but runs in a straight line between the transmission pinions 44b and the drive pinion 52.
  • one of the transmission pinions 44b can also form the drive pinion.
  • only one of the transmission pinions 44b needs to be provided with a nut, for example the cap nut 54 shown.
  • the separate drive pinion 52 Figure 7 and Figure 8 can then be omitted.
  • the in Figures 7 and 8 illustrated embodiments of the third embodiment only three radially movable retaining claws 22, which are evenly spaced from one another in the circumferential direction of the assembly unit 18.
  • the third embodiment can also have more or less radially movable retaining claws 22.
  • FIGS 9 to 14 show exemplary embodiments of a fourth embodiment of an emergency wheel attachment 10c.
  • the difference to the aforementioned three embodiments lies in the transmission of a rotary movement of the drive pinion 52 to the radially movable holding claws 22.
  • FIGS Figures 9 and 10 A first embodiment of the fourth embodiment is shown in FIGS Figures 9 and 10 shown and has an annular actuating disk 46c, which is provided with external teeth 86, which engage with the drive pinion 52 arranged here radially outside the actuating disk 46c.
  • an annular actuating disk 46c On the side of the actuating disk 46c facing the holding claws 22, a plurality of spiral segment-shaped elevations 88 are formed, viewed in the circumferential direction of the actuating disk 46c, each of which forms a spiral segment-shaped link 90.
  • each holding arm 36c facing this side of the actuating disk 46c several radially spaced sliding blocks are formed in the form of a short spiral segment-shaped rib 92, two of which interact with the link 90 formed by the spiral segment-shaped elevation 88 on the actuating disk 46c.
  • a rotation of the actuating disk 46c caused by a rotation of the drive pinion 52 causes each movable retaining claw 22 to move either radially outward or radially inward depending on the direction of rotation of the drive pinion 52.
  • each holding claw 22 in an initial state in a position that is radially further out or radially further inward, in order to accommodate different diameters of a vehicle wheel 12 to be able to take into account (for example 15 inches as the smallest size and 19 inches as the largest size of a vehicle wheel 12 on which the emergency wheel attachment 10c fits).
  • each retaining claw 22 is designed as a double claw with two circumferentially spaced retaining claw elements 94, which are separated from one another by a gap 96 and attached to the common retaining arm 36c. It is understood that such retaining claws designed as double claws can also be used in the previously discussed embodiments and in the embodiments discussed below.
  • two retaining claws 22 are each provided with two locating bolts 64. Such a configuration can also be used in the embodiments discussed above and described below.
  • the actuating disk 46c can have an internal toothing instead of the external toothing 86, in which case the drive pinion 52 is arranged radially within the actuating disk analogously to the first two embodiments.
  • Figure 13 shows a second exemplary embodiment of the fourth embodiment, in which the spiral segment-shaped elevations 88 each overlap slightly when viewed in the circumferential direction of the actuating disk 46c.
  • the spiral segment-shaped elevations 88 each overlap slightly when viewed in the circumferential direction of the actuating disk 46c.
  • several spiral segment-shaped links 90 formed by the elevations 88 are arranged radially next to one another. This makes it possible to achieve better power transmission from the actuating disk 46c to each holding arm 36c.
  • FIG 14 shows a third exemplary embodiment of the fourth embodiment, in which only a single, continuous spiral segment-shaped elevation 88 is arranged on the actuating disk 46c. It goes without saying that each holding arm 36c then only needs to have two spiral segment-shaped ribs 92 as sliding blocks (but can also have more than just two ribs 92).
  • FIGS 15 to 17 show a fourth and fifth exemplary embodiment of the fourth embodiment, in which the at least one or each spiral segment-shaped link 90 is formed by a spiral segment-shaped opening 98 in the actuating disk 46c.
  • the actuating disk 46c can have a single continuous spiral segment-shaped opening 98.
  • the actuating disk 46c has three spiral segment-shaped openings 98, viewed in the circumferential direction of the actuating disk, each of which is intended to cooperate with a retaining claw 22.
  • each holding claw 22 is provided with a sliding block in the form of a bolt 100, which is attached or formed on the holding arm 36c and is guided in the associated spiral segment-shaped opening 98.
  • every rotary movement of the drive pinion 52 which is arranged here radially within the actuating disk 46c, is converted into a radially directed translational movement of the holding claws 22 by the spiral segment-shaped links 90.
  • a drive pinion arranged radially outside the actuating disk can also be used, then in conjunction with an external toothing of the actuating disk 46c (the internal toothing of which can then be omitted).
  • Figures 16 and 17 show a fifth exemplary embodiment of the fourth embodiment, again with three spiral segment-shaped openings 98 spaced apart from one another in the circumferential direction of the actuating disk, the slope of which is, however, chosen to be steeper in the fifth exemplary embodiment than in the fourth exemplary embodiment.
  • This makes it possible to provide toothing of the actuating disk 46c, which is designed here as external toothing 86, only on part of the circumference of the actuating disk 46c, since further toothing is not required to move the maximum possible radial displacement path of the holding claws 22.
  • Figure 17 illustrates that the holding arm 36c of each holding claw 22 can be mounted in different radial positions with respect to the actuating disk 46c by providing radially spaced mounting holes 102 to enable adaptation to different wheel or rim sizes.
  • FIGS. 18 and 19 show a fifth embodiment of an emergency wheel attachment 10d with an internally toothed annular actuating disk 46d, which, analogous to the third embodiment, transmits a rotation of the drive pinion 52 to the holding claws 22 via transmission pinions 44b and rack-like teeth 84 or converts it into a radial movement of the holding claws 22.
  • Figure 19 shows a modification of this fifth exemplary embodiment, in which the in Figure 18 upper transmission pinion 44b has been provided with a cap nut 54 so that it can also serve as a drive pinion 52. This in Figure 18 The separate drive pinion 52 shown is therefore unnecessary.
  • Figure 20 shows an emergency wheel attachment 10 mounted on a vehicle wheel 12, for example according to the first or second embodiment, in which, to facilitate attachment of the mounting unit 18 to the vehicle wheel, the housing 60 of the mounting unit 18 is provided with a handle 104 which spans the free center of the housing 60, is attached to the housing 60 and is slightly arched outwards.
  • a handle 104 which spans the free center of the housing 60, is attached to the housing 60 and is slightly arched outwards.
  • Such or similar handle 104 makes it possible to hold the assembly unit 18 more easily during assembly on a vehicle wheel 12 and to press it against the vehicle wheel 12 or the rim 14.
  • Such or similar handle 104 can also be used in the other previously discussed embodiments.
  • FIGS 21 and 22 For a better understanding of the fastening process of the retaining claws 22, show a single retaining claw 22 in a state that each retaining claw 22 assumes at the start of fastening the assembly unit 18 to a vehicle wheel 12. This shows Figure 22 the cut AA Figure 21 .
  • Figure 22 It can be clearly seen that the hook-like curved, free end of the retaining claw head 24 must be inserted into a gap which is present between the tire 16 and the rim flange 26 of the rim 14 so that the retaining claw head 24 can reach behind the rim flange 26.
  • an end section 106 comprising the free end of the retaining claw head 24 can be provided with one or more recesses 108 on its surface facing the tire 16.
  • These recesses 108 which are approximately dome-shaped here, make it possible when the retaining claw head 24 is inserted into the space mentioned, that part of the rubber material of the tire 16 is pressed into the recesses 108 and thereby reduces the pressure required to insert the retaining claw head 24 the space mentioned must be used.
  • the recesses 108 thus make assembly easier.
  • each retaining claw 22 is provided with a display device which signals a correctly mounted state.
  • each retaining claw 22 is provided with a radially extending stop surface 110, with which it rests on an outside of the rim 14 when the emergency wheel attachment is correctly assembled.
  • this radial stop surface 110 there is a pin-shaped indicator element 112, which axially passes through the retaining claw in the area of the stop surface 110, and which is prestressed by a spring 114, which is arranged in a hole receiving the indicator element 112, so that in the unassembled state the holding claw 22, the end of the indicator element 112 facing the rim 14 protrudes from the radial stop surface 110.
  • the opposite, other end of the indicator element 112, which serves as an indicator, is then located deep in the hole mentioned when viewed from the outside and is therefore not or only poorly visible from the outside (see Figure 26 ).
  • each retaining claw 22 rests on the outside of the rim 14, which means that the end of the indicator element 112 facing the rim is now arranged flush with the stop surface 110.
  • the axially outer end of the indicator element 112 which serves as an indicator, is displaced so that it is clearly visible from the outside and thereby signals the correct assembly state.
  • this end of the indicator element 112 can be marked with green paint in order to indicate correct assembly by the appearance of the green marking in the part of the receiving hole that is visible from the outside.
  • FIGS. 28 and 29 explain a modified embodiment of a retaining claw 22.
  • a modified retaining claw 22 which can be used on any of the previously explained embodiments and exemplary embodiments, has a central contact section 116 for contacting the rim flange 26 and also at least one (here two) in the circumferential direction
  • the safety section 118 arranged on the contact section 116.
  • each safety section 118 does not rest on the rim flange 26 in the operating state of the emergency wheel attachment, but has a small distance x from the rim flange 26, which can be in the range of 0.2 to 0.5 mm and is preferably approximately 0.3 mm.
  • the contact section 116 is firmly clamped to the rim flange 26 in the operating state of the emergency wheel attachment.
  • Figure 30 shows a holding claw 22 designed as a double claw with two holding claw elements 94, which, in contrast to the one in the Figures 9 and 10 shown embodiment are further spaced apart in the circumferential direction.
  • Each retaining claw element 94 can be used as before in connection with Figures 28 and 29 explained with a contact section 116 and at least one security section 118.
  • FIG 31 shows a plan view of a further modified embodiment of a holding claw 22 designed as a double claw, in which each holding claw element 94 represents a separate element that is mounted on the common holding arm 36 so that it can rotate to a small extent about an axis Y runs perpendicular to a plane spanned by the common holding arm 36.
  • the extent of the possible rotational movement of each holding claw element 92 is determined by the spherical design of a side stop surface 120 on the holding arm 36 and an elongated hole 122 running in the circumferential direction, in which there is a fixing pin (not shown), which serves as a stop for the rotational movement of the holding claw element 94 .
  • Each retaining claw element 94 is as in Figure 31 shown rotatably mounted on the locating bolt 64.
  • each retaining claw element 94 comes into correct contact with the rim flange 26 in the course of the radial inward movement of a retaining claw 22. Any angular errors that can result from manufacturing inaccuracies, for example, are compensated for by automatically twisting the retaining claw elements during clamping.
  • FIGS. 32 and 33 show an embodiment of an emergency wheel attachment 10 according to one of the previously explained exemplary embodiments, which, in addition to the radially movable retaining claws 22, has at least one and preferably several self-bracing safety claws 124.
  • Each safety claw 124 is part of the tread unit 20 and therefore cannot be moved radially inward or radially outward by rotation of the drive pinion 52. Instead, each safety claw 124 has an actuating slide 126, which passes through the running surface 21 of the running surface unit 20 and protrudes radially from the running surface 21 in an initial state (see Figure 32 ).
  • the actuating slide 126 is biased radially outwards by a spring 128 acting on it. In this initial state of the safety claw 124, the safety claw 124 is not yet in engagement with the rim 14 of the vehicle wheel 12.
  • each safety claw 124 presses itself behind the rim flange 26 of the rim 14.
  • a position of the safety claw 124 is thus achieved which corresponds to that of a correctly mounted retaining claw 22.
  • no intervention by the user of an emergency wheel attachment 10 equipped in this way is required; rather, this position is reached automatically during operation of the emergency wheel attachment, which is why the safety claw 124 is referred to as self-bracing.
  • each safety claw 124 is equipped with a locking device which, after a radially inward displacement of the actuating slide 126, prevents the actuating slide 126 from moving radially outwards.
  • this locking device is formed by a lateral ribbing 130 on the actuating slide 126, which interacts with a sheet made of spring steel (not shown) that is positioned obliquely radially inward, the free end of this spring steel sheet locking into the lateral ribbing 130 places and thereby prevents a backward movement of the actuating slide 126 radially outwards.
  • ribbing 130 can alternatively or additionally also be present on the opposite side of the actuating slide 126 (also in cooperation with a spring steel sheet).
  • a safety claw 124 of the type described is preferably arranged between two radially movable retaining claws 22, viewed in the circumferential direction of the emergency wheel attachment.
  • one safety claw 124 can be located between two circumferentially adjacent retaining claws 22, so that such an embodiment has a total of three radially movable retaining claws 22 and three safety claws 124.
  • Other combinations are of course possible.
  • the tread unit 20 is fastened to the mounting unit 18 in some embodiments by tightening nuts on receiving bolts designed as threaded bolts with a predetermined torque. So that a user can easily recognize when this prescribed torque has been reached, according to one embodiment, these nuts are designed as cap nuts 76, with each cap nut 76 containing an optical and / or acoustic display device that signals a correct assembly state. An exemplary embodiment of such a cap nut 76 is shown in FIG Figures 34 to 36 shown.
  • Figure 35 shows such a cap nut 76 in a starting position.
  • a plunger 132 which is supported by a spring plate 134, which is in the in Figure 35 shown starting position is biased axially inwards and is supported on the upper inside of the cap nut 76.
  • the larger diameter inside 136 of the plunger 132 is intended to come into contact with the free end of a locating bolt 64 (not shown), onto which the cap nut 76 is to be screwed.
  • the axially inward force of the spring plate 134 is exceeded and the plunger 132 jumps axially outwards into a second position, in which a preferably colored marked Indicator element 138 is flush with the outer surface of the cap nut 76 (see Figure 36 ).
  • the “jumping” of the spring plate 134 into the in Figure 36 The position reproduced can be heard acoustically.
  • the indicator element 138 which is flush with the outer surface of the cap nut 76, indicates that the correct assembly state of the tread unit 20 on the assembly unit 18 has now been achieved.
  • the plunger 132, the spring plate 134 and the indicator element 138 are part of a display device 131, which is fastened as a unit in the cap nut 76.
  • a housing of the display device 131 consists of a ring nut 133 and a cover 135.
  • the cover 135 is screwed into the ring nut 133 from above and braces the spring plate 134 against the plunger 132.
  • the ring nut 133 is in turn screwed into an internal thread of the cap nut 76, which is open at the top (The nut 76 only becomes a cap nut here through the cover 135).
  • the indicator element 138 is guided in a central hole in the cover 135.
  • each locking device 140 comprises a radially movable slide 142, which is attached to the outside of the housing 60 of the assembly unit 18, more precisely on the cover 56 of the assembly unit 18, by means of four screws 144, two of which in the exemplary embodiment shown are secured by one on the Top of the slide 142 formed and essentially radially extending elongated hole 146 extend.
  • each slide 142 which in the exemplary embodiment shown is fastened to the radially inner edge of the cover 56 of the assembly unit 18, for example by screws, rivets or the like, but the holding bracket can also be integral with the cover be cast or welded onto the cover 56 be.
  • the holding bracket 150 serves to support a spring 152, which resiliently biases the slide 142 radially outwards.
  • each slide 142 is designed as an oblique ramp or surface 154, which comes into contact with an associated surface or edge of the tread unit 20 when mounting the tread unit 20 or the segments 68, 70 of the tread unit 20, so that when pressed of the tread unit 20 or a segment 68, 70 of the same in a direction axially directed towards the assembly unit 18, the slide 142 is initially displaced radially inwards until the outside of the tread unit 20 facing away from the vehicle wheel 12 has passed the underside of the slide 142.
  • the drive pinion 52 when mounting the mounting unit 18 on a vehicle wheel 12, the drive pinion 52 is actuated in rotation until a prescribed torque is reached, which ensures that all radially movable retaining claws 22 rest securely on the rim flange 26.
  • the drive pinion 52 which is coupled or can be coupled to the actuating element, is equipped with a torque limiting device.
  • Such a torque limiting device is located according to one in Figure 39 shown embodiment in the cap nut 54 of the drive pinion 52 and consists of several spring washers 156 arranged one above the other and in mutual contact, which prevent more than a predetermined torque from being introduced into the emergency wheel attachment 10 when the drive pinion 52 is rotated in the manner of a slip-plate clutch.
  • the package of spring washers 156 only transmits any rotational movement of the cap nut 54 to the drive pinion 52 until the friction force between the spring washers 156 set by a corresponding preload of the spring package is exceeded.
  • the individual spring washers 156 "slip" relative to one another in the circumferential direction, so that any further rotational movement can no longer reach the drive pinion 52.
  • slip clutch consists of two mutually facing clutch disks 158 and 160, which are each formed on their mutually facing surfaces with pie-slice-like elevations 162 and pie-slice-like depressions 164 arranged alternately in the circumferential direction.
  • each flank 166 of an elevation 162 and the associated flank 168 of the corresponding recess 164 are designed to be beveled, so that when a torque is exceeded, which is defined by a spring force pressing the clutch disks 158, 160 against one another, the clutch disk 158 over the clutch disk 160 begins to slip, which, as in the previously described exemplary embodiment, prevents the rotational movement from being passed on to the drive pinion 52.

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Tires In General (AREA)
  • Auxiliary Drives, Propulsion Controls, And Safety Devices (AREA)
  • Vehicle Cleaning, Maintenance, Repair, Refitting, And Outriggers (AREA)
  • Inorganic Insulating Materials (AREA)
  • Rolling Contact Bearings (AREA)
EP21707983.9A 2020-02-28 2021-02-24 Notradaufsatz für ein fahrzeugrad Active EP4110624B1 (de)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE102020001324.4A DE102020001324A1 (de) 2020-02-28 2020-02-28 Notradaufsatz für ein Fahrzeugrad
PCT/EP2021/054558 WO2021170657A1 (de) 2020-02-28 2021-02-24 Notradaufsatz für ein fahrzeugrad

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EP4110624A1 EP4110624A1 (de) 2023-01-04
EP4110624B1 true EP4110624B1 (de) 2023-11-15

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EP (1) EP4110624B1 (pt)
JP (1) JP2023521546A (pt)
KR (1) KR20220147606A (pt)
CN (1) CN115279600A (pt)
AU (1) AU2021225352A1 (pt)
BR (1) BR112022015625A2 (pt)
CA (1) CA3170028A1 (pt)
DE (1) DE102020001324A1 (pt)
ES (1) ES2967004T3 (pt)
MX (1) MX2022010658A (pt)
WO (1) WO2021170657A1 (pt)

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DE102017101664A1 (de) * 2017-01-27 2018-08-02 Gv Engineering Gmbh Aufsatz für ein Fahrzeugrad
DE102017103101A1 (de) * 2017-02-15 2018-08-16 Gv Engineering Gmbh Notlaufaufsatz für ein Fahrzeugrad
DE102018111492A1 (de) * 2018-01-22 2019-07-25 Gv Engineering Gmbh Notlaufrad

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Publication number Priority date Publication date Assignee Title
GB857897A (en) * 1958-04-26 1961-01-04 Porsche Ferdinand A Improvements in or relating to auxiliary supports for motor vehicles
FR2620977A1 (fr) * 1987-09-24 1989-03-31 Ferran Richars Vehicule pourvu de moyens de montage de roues auxiliaires
CN102582378B (zh) * 2011-01-06 2017-03-15 周立新 轮胎、轮胎安装与拆卸系统
CN103144332A (zh) * 2011-12-07 2013-06-12 软控股份有限公司 胎体组件传递装置及其传递方法
CN202693338U (zh) * 2011-12-16 2013-01-23 李向阳 四轮定位夹具
CN106114054A (zh) * 2016-06-27 2016-11-16 无锡康柏斯机械科技有限公司 一种车轮脱离时能够代替车轮的安全辅助轮装置
DE102017101664A1 (de) * 2017-01-27 2018-08-02 Gv Engineering Gmbh Aufsatz für ein Fahrzeugrad
DE102017103101A1 (de) * 2017-02-15 2018-08-16 Gv Engineering Gmbh Notlaufaufsatz für ein Fahrzeugrad
DE102018111492A1 (de) * 2018-01-22 2019-07-25 Gv Engineering Gmbh Notlaufrad
CN109365973B (zh) * 2018-12-10 2020-11-03 温州大学瓯江学院 一种可自动定心装夹的焊接设备

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BR112022015625A2 (pt) 2022-09-27
US20230098604A1 (en) 2023-03-30
CN115279600A (zh) 2022-11-01
WO2021170657A1 (de) 2021-09-02
CA3170028A1 (en) 2021-09-02
AU2021225352A1 (en) 2022-08-25
JP2023521546A (ja) 2023-05-25
MX2022010658A (es) 2022-09-23
ES2967004T3 (es) 2024-04-25
DE102020001324A1 (de) 2021-09-02
EP4110624A1 (de) 2023-01-04

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